Two Cycad Species Affect the Carbon, Nitrogen, and Phosphorus Content of Soils

The influences of Cycas micronesica and Zamia integrifolia plants on soil chemistry were determined in Tinian and Florida in order to more fully understand how cycad plants affect the environments in which they grow. The introduction of C. micronesica plants into a karst habitat generated decreases...

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Bibliographic Details
Published in:Horticulturae 2020-06, Vol.6 (2), p.24
Main Authors: Marler, Thomas, Calonje, Michael
Format: Article
Language:English
Subjects:
Ammonification
Biogeochemistry
Carbon
cycad
Cycads
Cycas micronesica
Environmental aspects
Environmental changes
Forest soils
Germplasm
Gymnosperms
Heterogeneity
Karst
Leaves
Lithic
litter-trapping plants
Mineralization
Nitrification
Nitrogen
Nitrogen (Nutrient)
Nutritional aspects
Phosphorus
Phosphorus (Nutrient)
Pine trees
Private property
Scientific imaging
Soil chemistry
Soils
Spatial heterogeneity
stemflow
Stoichiometry
Studies
Substrates
Zamia integrifolia
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Summary:The influences of Cycas micronesica and Zamia integrifolia plants on soil chemistry were determined in Tinian and Florida in order to more fully understand how cycad plants affect the environments in which they grow. The introduction of C. micronesica plants into a karst habitat generated decreases in soil phosphorus after five years and increases in soil nitrogen after six years. The carbon:nitrogen:phosphorus stoichiometry beneath the cycad plants significantly diverged from those of the adjacent native forests with Pisonia grandis, Psychotria mariana, Aglaia mariannensis, Cynometra ramiflora, and Ficus sp. cover after five years. Mineralization traits were determined beneath nine-year-old C. micronesica plants and revealed the plants greatly increased net nitrification and decreased net ammonification when compared to the native forest soils with Bursera simaruba, Pinus elliottii, and Quercus virginiana cover. These flux changes increased the total available nitrogen and percent available nitrogen in the soils beneath the cycad plants. The substrates of two soil series exhibited increased carbon and nitrogen concentrations beneath Z. integrifolia plants when compared with soils away from the cycad plants. No other mineral or metal was influenced by proximity to the Z. integrifolia plants. These gymnosperms exhibit distinct interactions with their subtending soils, and some of these traits improve ecosystems by increasing recalcitrant carbon and nitrogen and increasing spatial heterogeneity of soil chemistry.
ISSN:2311-7524
2311-7524
DOI:10.3390/horticulturae6020024